msa geographic allocations, property selection, and performance
TRANSCRIPT
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MSA Geographic Allocations, Property Selection, and Performance Attribution in Public and Private Real Estate Market Returns
by
David C. Ling*, Andy Naranjo*, and Benjamin Scheick+
*Department of Finance, Insurance, and Real Estate Warrington College of Business Administration
University of Florida Gainesville, Florida 32611
Email: [email protected]; [email protected] Phone: (352) 273-0313; (352) 392-3781
+Department of Finance
Villanova School of Business Villanova University
Villanova, Pennsylvania, 19085 Email: [email protected]
Phone: (610) 519-7994
Current Draft: April 2015
Abstract: This paper examines the impact of differences in geographic portfolio concentrations on comparisons of return performance of U.S. public and private commercial real estate investors over the 1996-2013 time period. Returns are carefully adjusted for differences between public and private markets in financial leverage, property type focus, management fees, and geographic concentrations. With these adjustments, we are able to more accurately assess the relative performance of “geographically identical” public and private market portfolios. Furthermore, through formal attribution analysis we are able to provide insights on whether relative return performance is attributable to differences in MSA allocations versus individual property selection and management within MSAs. In particular, we find that the allocation effect constitutes a small portion of the total return difference, relative to the selection plus interaction effects. This indicates that the decision to allocate to a particular MSA is relatively less important than the manager’s ability to select properties within that MSA.
We thank the National Association of Real Estate Investment Trusts for proving partial funding for the research.
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1. Background and Motivation
Both direct private and public REIT markets can provide investors with exposure to the same
underlying local property markets. However, as commonly measured, public and private real estate
returns often exhibit significantly different risk-return characteristics, especially in the short-run. For
example, several studies find that investments in direct private real estate, as proxied for by the
National Council of Real Estate Investment Fiduciaries (NCREIF) Property Index (NPI), produce lower
average returns than comparable investments in publicly-traded real estate investment trusts (REITs),
even after controlling for differences in financial leverage, property mix, and management fees
(Riddiough et al., 2005; and Tsai, 2007).
More recently, Ling and Naranjo (2015) find that passive portfolios of unlevered core REITs
(unconditionally) outperformed their private market benchmark by 49 basis points (annualized) over
the 1994-2012 sample period. Although Ling and Naranjo (2015) carefully control for (firm-level)
leverage, property type, and management fees in their comparisons of public and private market
returns, they do not adjust for differences in the geographic MSA composition of underlying properties.
As a result, the authors are unable to determine the extent to which the measured outperformance of
equity REITs over their sample period is attributable to the magnitude and timing of MSA-level
property sector allocations and/or individual property selection within these MSAs. Ling and Naranjo
(2015) conclude that future research should attempt to address the extent to which public and private
market performance differences are attributable to differences in the geographic distribution of REIT-
owned properties relative to NCREIF properties. In this paper, we examine MSA geographic
allocations, property selection, and performance attribution in public and private market real estate
returns.
Prior research investigating the extent to which geographic allocations and property type
selection affect value has yielded mixed results. Gyourko and Nelling (1996), Capozza and Seguin
(1998) and Ambrose et al. (2000) find no economic benefit to geographic concentration. In contrast,
Campbell et al. (2003) find that announcements of portfolio acquisitions by REITs are greeted more
favorably if they reconfirm the buyers’ geographic focus. Capozza and Seguin (1999) provide some
additional evidence suggesting that REITs that are more diversified across property types (but not
across geography) are in fact penalized. However, Hartzell et al. (2014) find that REITs diversifying
into more locations tend to be valued lower than REITs with tighter geographic focus. In terms of asset
selection, Cici et al. (2011) find that fund managers generate significant positive alpha with their
selection ability but that geographic concentration strategies do not explain selection outperformance.
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More recently, Hochberg and Muhlhofer (2014) find that REIT managers generally exhibit little
market timing ability, but positive selection ability.
Our research contributes to this related research stream by examining the effects of geographic
concentrations of real estate holdings on the relative return performance of US public and private real
estate markets. In particular, we assess relative performance after carefully adjusting for differences
in the geographic composition of property portfolios in these two markets. We then decompose
performance differences into allocation, selection, and interaction effects through a formal attribution
analysis.
To measure the MSA risk exposures of publicly-traded equity REITs, we first obtain time-
varying property level location data from SNL’s Real Estate Database. From this information, we
compute the percentage allocations of equity REIT portfolios to each MSA at the beginning of each year
based on various size measures. This allows us to compare the MSA concentrations of publicly-traded
REITs, by core property type (i.e., apartments, industrial, office, and retail), to the MSA concentrations
of the properties in the NCREIF database over the 1996-2013 sample period. We then calculate the
extent to which adjusting for these differences in MSA exposure affects the NPI returns reported by
NCREIF. This is accomplished by obtaining quarterly MSA-level NCREIF NPI returns for the four
core property types and then reweighting these MSA-level returns to create returns for each core
property type using the same time-varying MSA weights observed in the REIT data. With these careful
adjustments, we are able to more accurately compare the geographically reweighted NPI returns to
unlevered REIT returns and thereby assess the relative performance of “geographically identical”
public and private market portfolios. We attribute performance differences after geographically
reweighting NCREIF NPI returns to property (asset) selection within MSAs.
We document significant differences in geographic allocations of property portfolios between
public and private markets. These differences vary significantly over time and across property type
classifications. We further establish how accounting for time-series and cross-sectional differences in
the geographic concentrations of the properties held by core equity REITs and NCREIF investors can
significantly impact the performance comparison across markets. Adjusting private markets for
differences in geographic concentrations with public markets, we find that core private market
performance falls, consistent with the documented negative geographic allocation valuation effects in
the prior literature. Focusing on property types, we find the biggest return difference in the retail
sector. The benchmark return for retail NPI properties is 10.0 basis points lower than the
corresponding quarterly unadjusted NPI return over our sample period; thus, its use in place of the
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unadjusted NPI retail return decreases the measured relative performance of NCREIF investors. In
contrast, the reweighted mean returns for industrial and office properties are 2.5 and 3.8 basis points,
respectively, greater than the corresponding unadjusted quarterly NPI return. Thus, using reweighted
returns slightly increases the average performance of industrial and office NCREIF investors relative
to the performance of REIT investors in these property types over the 1996-2013 sample.
In addition to providing an improved methodology for comparing public and private market
portfolio returns that controls for differences in geographic concentrations across investor groups, we
also provide insights as to the importance of geographic allocation on relative return performance. We
find that the allocation effect constitutes a small portion of the total return difference, relative to the
selection plus interaction effects. This result indicates that the decision to allocate to a particular MSA
is relatively less important than the manager’s ability to select properties within that MSA, consistent
with Capozza and Seguin’s (1999) positive selection effect hypothesis. However, the sign and
magnitude of the allocation effect varies significantly over the sample period and property type being
examined.
The remainder of the paper proceeds as follows. The next section provides an initial comparison
of public and private market performance over the 1996-2013 sample without any adjustments for
differences in geographic allocations across markets. Section 3 describes our MSA level data and
discusses our methodology for adjusting benchmark returns for differences in MSA concentrations.
Section 4 presents a formal attribution analysis that examines whether differences in returns between
public and private markets are attributable to differences in MSA allocations versus individual
property selection and management within MSAs. Section 5 provides a simplified example of how our
methodology can provide managers with an additional tool for analyzing firm performance at the
individual firm level. In the final section, we provide concluding remarks.
2. Public vs. Private Market Returns: 1996-2013
It is well known that significant differences in financial leverage and property type mix
complicates performance comparisons across public and private markets (Riddiough et al., 2005; and
Tsai, 2007; Ling and Naranjo, 2015). To render total returns on equity REIT portfolios comparable to
unlevered private market returns, it is necessary to adjust the composition and risk characteristics of
publicly-traded REIT portfolios to match as closely as possible the composition and characteristics of
their benchmark private market portfolios. Following the methodology of Ling and Naranjo (2015), we
(1) remove the effects of financial leverage from firm-level REIT returns, (2) exclude from the final
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analysis those equity REITs that do not invest in core property types, and (3) construct unlevered total
return series for each of the four core property classifications.1
Our initial list of publicly-traded U.S. equity REITs is obtained from the CRSP-Ziman database.
We collect the following data for each REIT at the beginning of each quarter: REIT identification
number, property type and sub-property type focus, and equity market capitalization. We also obtain
levered monthly total returns for each REIT in our sample from CRSP-Ziman, which we then
compound to produce the levered total return on equity for each REIT in a particular quarter.
We obtain the balance sheet and income statement information necessary to unlever quarterly
returns at the firm level by merging our initial REIT sample with data collected from the quarterly
CRSP/Compustat database. We delete REITs that do not invest primarily in the four core property
types. A detailed explanation of the delevering process and property type adjustments used to create
the unlevered return series for core REITs is available in the Appendix.
Our primary source of return data in the private commercial real estate market is the National
Council of Real Estate Investment Fiduciaries (NCREIF). Established in 1982, NCREIF is a not-for-
profit industry association that collects, processes, validates, and disseminates information on the
risk/return characteristics of commercial real estate assets owned by institutional (primarily pension
and endowment fund) investors (see www.ncreif.org). NCREIF’s flagship index, the NCREIF Property
Index (NPI), tracks property-level quarterly returns on a large pool of properties acquired in the
private market for investment purposes only. The property composition of the NPI changes quarterly
as data contributing NCREIF members buy and sell properties. However, all historical property-level
data remain in the database and index.
Any analysis of the relative return performance between public and private real estate returns
must address the well-known smoothing and stale appraisal problems associated with the NCREIF
NPI.2 Our solution is to compare public and private market returns over time horizons of at least six
1 A REIT is included in our retail index if it is classified by CRSP-Ziman as having a property type focus of 9 (retail) and a sub-property type focus of 5 (freestanding), 14 (outlet), 15 (regional), 17 (shopping center), or 18 (strip center). Our industrial index includes REITs classified by CRSP-Ziman as having a property type focus of 4 (industrial/office) and a sub-property type focus of 8 (industrial). Our quarterly office sample includes REITs with a property type focus of 4 (industrial/office) and a sub-property type focus of 13 (office). Finally, a REIT is included in our apartment index in a given quarter if it is assigned by CRSP-Ziman a property type focus of 8 (residential) and a sub-property type focus of 2 (apartments). 2 Unless a constituent property happens to sell during the quarter, the reported quarterly capital gain on an individual property within the NCREIF NPI is based on the change in the property’s appraised value. Appraisal-based indices are thought to suffer from two major problems. First, estimated price changes lag changes in “true” (but unobservable) market values; this smoothing of past returns understates return volatility. Second, formal appraisals of constituent properties in the NCREIF Index by third party appraisers are usually conducted
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years. Such an approach largely mitigates the problems associated with smoothing and stale
appraisals.3
Table 1 reports quarterly geometric means of our unlevered equity REIT returns (Panel A),
unlevered raw NPI returns (Panel B), and the difference in geometric means across markets (Panel C)
for the following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013. We report mean returns
for each of the four core property types, as well as an aggregate core property type series. Consistent
with Ling and Naranjo (2015), we find that portfolios of unlevered core REITs (unconditionally)
outperform their private market benchmark from 1996-2013. However, the magnitude of this
outperformance is smaller (22 basis points annually) due to our slightly different sample period.
Further evaluation of Table 1 reveals that comparisons of public and private market return
performance are sensitive to the time period selected for the analysis and the property type being
examined. Focusing on the comparison of our core return series, the outperformance of equity REITs is
concentrated in the most recent recovery period (2008-2013) as REITs outperformed their private
market benchmark by 81 (328) basis points quarterly (annually). However, from 1996-2001 and 2002-
2007, core REITs underperformed their private market benchmark by 25 (98) and 42 (165) basis points
quarterly (annually), respectively. Moving on to individual property types, apartment, office, and retail
REITs all outperformed the raw NPI series in the recent recovery period (2008-2013). However, in
earlier sub-periods, only retail REITs (from 1996-2001) and industrial REITs (from 2002-2007)
outperformed their private market benchmarks. These comparisons further underscore the importance
of controlling for the mix of property types and carefully considering the appropriate investment
horizon when comparing the relative performance of REIT and private market return series as
suggested by Ling and Naranjo (2015).
3. Differences in MSA Allocations
The return differences reported in Panel C of Table 1 control for differences in leverage and
property type. However, these return differences do not account for time-series and cross-sectional
differences in the geographic concentrations of the properties held by core equity REITs and the data
contributing members of NCREIF (primarily pension and endowment funds). Thus, we are unable to
annually; the property’s asset manager is responsible for updating the appraisal internally in the intervening quarters. This leads to what is commonly called the “stale” appraisal problem. 3 In addition to the NPI, NCREIF also produces a suite of Transaction Based Indices (TBIs). An advantage of the TBI indices is that the capital gain component of the TBI in each quarter is based only on the constituent properties in the NCREIF database that were sold that quarter. The TBI indices are available from NCREIF at the national level back to 1994Q1 for multifamily, office, industrial, and retail properties. However, these core TBI indices are not available at the MSA level, which precludes their use in this research.
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determine the portion of public-private performance differences that are attributable to MSA
allocations versus property selection and asset management within MSAs.
To examine the importance of time-varying geographic concentrations, we collect the following
data from SNL’s Real Estate Database on an annual basis for each property held by an equity REIT
during the period 1996 to 2013: the property owner (institution name), property type, geographic
location (MSA), acquisition date, sold date, book value, initial cost, and historic cost. Our analysis
begins in 1996 (end of 1995) since this is the first period for which SNL provides historic book value
and cost information at the property level. Although the property composition of the aggregate REIT
portfolio changes as properties are bought and sold, all historical property-level data remain in the
SNL database.
Over our 1996-2013 sample, we have 517,131 property-year observations in our dataset. At the
beginning of 1996, equity REITs held 15,752 properties with a reported book value of over $34 billion.
The corresponding property counts and book values for core equity REITs are 9,420 and $25 billion,
respectively. By 2013, equity REITs owned 32,707 properties with a reported book value of over $419
billion. Core REITs held 15,510 properties with a reported book value of $242 billion. After excluding
non-core REITs, 291,894 property-year observations remain.
To construct our time-varying measures of geographic allocations, we first sort equity REITs by
their CRSP-Ziman property type and property subtype classifications. We then sort each core REIT’s
properties into MSA categories that mirror those MSAs tracked by the NCREIF NPI within a
particular year. We compute the percentage of the REIT portfolio held in an MSA by REITs of property
type f at the beginning of year T as follows:
, , ∑ , ,
,
∑ ∑ , ,,
, 1
where , , is the reported book value of property i in Metropolitan Statistical Area m at the
beginning of year T.4 The total number of core properties in a particular MSA at the beginning of year
T is denoted as Nm,T. The total number of NCREIF MSA classifications as of the beginning of year T is
denoted as NT.
As a robustness check, we create two additional time-varying geographic concentration
measures for each of the four property types. First, we replace the book value of each property by its
4 SNL’s net book value variable (SNL Key Field: 221784) is defined as the historical cost of the property and improvements, net of accumulated depreciation.
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“adjusted cost” (ADJCOST) at the beginning of each year, defined by SNL as the maximum of (1) the
reported book value, (2) the initial cost of the property, and (3) the historic cost of the property
including capital expenditures and tax depreciation.5 In a separate analysis, we also weight each
property by a simple property count variable (PROPCOUNT), which takes a value of 1 for each unique
property observation.
To compare the geographic exposure of the NCREIF portfolio with that of our sample of equity
REITs, we calculate geographic concentrations for each of the four core property NCREIF NPI
portfolios as follows:
, , ∑ , ,
,
∑ ∑ , ,,
, 2
where , , is the market (appraised) value of property i in Metropolitan Statistical Area m at the
beginning of year T. The total number of properties of type f in a particular MSA at the beginning of
year T is denoted as Nm,T. The total number of MSA classifications as of the beginning of year T is
again denoted as NT.
At the beginning of 1996, the NCREIF NPI was composed of 2,379 core properties with an
estimated market value of $50 billion. NCREIF does not report a quarterly return for property type f in
MSA m unless there are at least four properties available for the return calculation. This is done to
protect the identity of the individual properties and owners. We classify the MSA location of any
properties held outside of these listed MSAs as “Other.” The NPI contained four or more apartment,
industrial, office, or retail properties in 58 MSAs, with its greatest concentration in Washington, D.C.
(7.1 percent). In comparison, equity REITs held 6.5 percent of their core portfolio (based on book value)
in the D.C. area. By the beginning of 2013, the NPI index contained 6,968 core properties with an
estimated market value of $366 billion. The NPI database contained four or more of one of the core
properties in 106 MSAs, with its greatest concentration in New York (10.4 percent). In comparison,
equity REITs held 13.8 percent of their core assets in New York in 2013.
3.1. Allocations to Gateway MSAs
Much has been written by industry professionals about the desirability of investing in major
“gateway” MSAs, most frequently defined as Boston, Chicago, Los Angeles, New York, San Francisco,
5 SNL’s initial cost variable (SNL Key Field: 221778) is defined as the historic cost currently reported on the financial statements, which may be different than the cost reported at time of purchase. SNL’s historic cost variable (SNL Key Field: 221782) is defined as the book value of the property before depreciation.
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and Washington, D.C. These MSAs are thought to have significant investment advantages over the
remaining 300-plus MSAs, including increased liquidity, due to the size and depth of these markets, as
well as constraints on the production of new supply that puts upward pressure on rental rates.
Therefore, the degree to which public and private market investors allocate investment capital to these
markets, and the timing of these investments, may be an important determinant of their portfolio’s
performance.
In Figure 1, we present the concentrations of equity REIT and NCREIF core properties located
in gateway MSAs. At first glance, both REIT and NCREIF investors appear to hold a similar
proportion of core assets in these six major markets. On average, NCREIF investors held
approximately 34 percent of their portfolio in gateway MSAs over our sample period; equity REITs
held approximately 32 percent of their core assets in these six metropolitan areas.
Although investment allocations to gateway markets appear to be similar on average, we
observe differences in allocations over time and by property type. For example, REITs held a slightly
larger portion of their core portfolio in gateway MSAs during the period of real estate expansion from
2003 to 2006. In 2006, over 35 percent of the equity REIT portfolio was concentrated in gateway
markets. However, as the recent credit crisis unfolded, NCREIF investors held a significantly higher
proportion of their portfolio in these six cities. In fact, in 2008 NCREIF investors increased their
concentrations in gateway MSAs to constitute nearly 40 percent of their core portfolio.
Figure 2 presents the concentrations of equity REIT and NCREIF properties located in gateway
MSAs, disaggregated by property type. In Panel A, we present allocations to gateway MSAs for
apartment properties. Panels B-D of Figure 2 display geographic concentrations in these six markets
for industrial, office, and retail properties, respectively.
There are several key takeaways from these comparisons. First, within a particular year there
are often significant differences between the proportion of properties held by NCREIF data
contributing members and those held by equity REITs in gateway markets. For example, in 2003
equity REITs held approximately 50 percent of their industrial assets in gateway cities (Figure 2,
Panel B). During the same year, NCREIF investors held just 21 percent of their industrial property
portfolio in these six major markets. During most of our sample period, equity REITs hold larger
portions of their apartment, industrial, and office properties in gateway cities. Since 2003, however,
NCREIF investors have been significantly more exposed to gateway retail than equity REITs.
Second, we observe significant variation in the time-series distribution of these portfolio
concentrations. For example, from 2000-2013 equity REITs increased the concentration of their
apartment portfolios in gateway markets from approximately 10 percent to nearly 50 percent. This
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represents a massive reallocation of REIT apartment portfolios to gateway markets. In contrast, from
2000-2013 NCREIF investors increased their exposure to gateway apartment properties from nearly
11 percent to approximately 35 percent. Moreover, private market investors decreased their gateway
apartment allocations during the 2009-2013 period.
For industrial properties, we also observe a significant negative correlation between changes in
gateway allocations by equity REITs and NCREIF investors. For example, from 2004-2008 equity
REITs shifted their industrial portfolio away from gateway cities, decreasing their holdings from over
50 percent of their portfolio to approximately 34 percent. During this same period NCREIF investors
increased the proportion of industrial properties owned in these markets from 19 percent to 28 percent
of their portfolio. Nevertheless, industrial REITs retained much larger allocations to gateway markets
than their private market counterparts.
In contrast, changes in portfolio holdings in gateway markets within the office property type
appear to be positively correlated across investor types for much of our sample period. From 2000-2008
both equity REITs and NCREIF investors significantly increased their office holdings in gateway cities
by 20 percent and 10 percent, respectively. From 2008-2013, at least 65 percent of office REIT assets
were located in these six markets.
In the retail sector, however, there is less correlation between changes in concentration across
investor groups. Since 2005, equity REITs have maintained a fairly consistent allocation to gateway
markets in their retail portfolios, ranging from 18 percent to 20 percent. In contrast, NCREIF investors
have reduced their allocations to gateway retail from 30 percent to 20 percent during the same period.
In comparing public and private market geographic concentrations across property types, it is evident
that differences exist within a particular year and across time.
As we narrow our focus to portfolio concentrations in specific gateway cities, the points observed
previously at the aggregate level become more evident. In Panel A of Figure 3, we present the
concentrations of equity REIT and NCREIF apartment properties located in Chicago. The
corresponding Chicago exposures for industrial, office, and retail properties are presented in Panels B-
D, respectively. Figures 4-8 display core property geographic concentrations for the remaining five
gateway MSAs: Los Angeles, New York, Washington, D.C., Boston, and San Francisco, respectively.
As observed in the aggregate data, there are significant differences between the proportion of
properties held by NCREIF data contributing members and those held by equity REITs, significant
variation in the time-series distribution of these portfolio concentrations, and notable differences
across property types when comparing public and private market geographic concentrations within a
gateway MSA. For example, in 2013 NCREIF investors held approximately 7.0 percent of their
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apartment assets in Chicago. During the same year, equity REITs held approximately 1.0 percent of
their apartment assets in Chicago. From 2006 to 2013, NCREIF investors substantially increased the
concentration of their apartment portfolios in Chicago, while equity REITs were decreasing their
exposure to apartment properties in Chicago during this period. These are strikingly different “bets” on
the attractiveness of the Chicago apartment market. In contrast, since at least 2006 public and private
market investors have allocated similar proportions of their capital to Chicago industrial and office
properties. Finally, in recent years NCREIF investors have been significantly more exposed to Chicago
retail properties than retail REITs.
There are also noticeable differences in how NCREIF investors and equity REITs allocate their
portfolios to specific gateway markets within property types. For example, apartment REITs hold a
relatively larger proportion of their apartment assets in Los Angeles, Washington, D.C., Boston, and
San Francisco; in contrast, NCREIF investors tend to dedicate greater concentrations of their
apartment portfolio to Chicago than equity REITs. The two groups of investors hold similar
proportions of their apartment portfolio in New York.
In the retail property type, NCREIF investors concentrate a greater proportion of their holdings
in Chicago, Los Angeles, Washington, D.C., and San Francisco; in contrast, equity REITs have chosen
to concentrate their retail portfolio in New York and Boston. Equity REITs hold a significantly larger
proportion of industrial properties in New York, Washington, D.C., and San Francisco. However,
allocations to industrial properties in Chicago and Boston have historically been similar across the two
investor groups. Finally, in the office property type we observe less variation across investor group.
NCREIF investors and equity REITs hold comparable portions of their office portfolios in each of the
six gateway markets.
Overall, it is clear that the MSA composition of NCREIF and REIT apartment, industrial, office,
and retail properties at a particular point in time often varies significantly across gateway markets;
moreover, these relative allocations can vary significantly over time. It is therefore important to
understand the extent to which these differences in MSA allocations affect the return performance of
public and private market investors, both in the short- and long-run.
3.2. Have Gateway MSAs Outperformed?
To determine how these differences in allocations may impact portfolio returns it is important
to first establish that there are in fact significant performance differences between gateway and non-
gateway markets. To conduct this analysis, we begin with quarterly NCREIF NPI returns
disaggregated by property type and MSA. We then create a value-weighted gateway return series for
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each property type, as well as an aggregate core property series, in which the weights are the market
(appraised) values of properties held by NCREIF within each of the six gateway cities as of the
beginning of the year. Similarly, we construct value-weighted non-gateway return series in which the
weights are the market (appraisal) values of properties held by NCREIF in each of the remaining non-
gateway cities.6
Table 2 reports quarterly geometric means of our gateway NPI returns (Panel A), non-gateway
NPI returns (Panel B), and the difference in geometric means between gateway and non-gateway
returns (Panel C) for the following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013. We
report mean returns for each of the four core property types, as well as an aggregate core property type
series. Focusing on our full sample period (1996-2013), gateway markets outperform non-gateway
markets for all property type classifications, including the aggregate core series. In fact, the only
indication of underperformance in gateway markets appears in the recovery period for apartment and
industrial properties. Focusing on our core property type series, gateway markets outperform non-
gateway markets by 26 (106) basis points quarterly (annually) over the 1996-2013 sample period. The
most significant difference in performance between gateway and non-gateway markets at the property
type level is in the office sector. Over our full sample period, gateway office outperformed non-gateway
office by 44 (177) basis points quarterly (annually). During the period of rapid expansion in commercial
real estate markets (2002-2007), this return difference was even larger as gateway markets
outperformed non-gateway markets by 96 (387) basis points quarterly (annually).
To further establish differences in performance across MSAs, Table 3 reports quarterly
geometric means of NPI returns for each of the six gateway cities by core property type for the
following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013. Within property type, there is
significant variation in returns across the six gateway markets. In addition, the relative performance
varies significantly with the particular sample period being examined. For example, in the apartment
property type, Washington, D.C. outperforms the remaining five gateway markets over the full sample.
However, in the recovery period (2008-2013), Washington, D.C. underperforms San Francisco, Boston,
and Chicago apartments. Since equity REITs tend to hold a larger proportion of their apartment
portfolio in Washington, D.C. than NCREIF investors, particularly in the recovery period, we expect
this difference in geographic concentrations to significantly impact the comparison of portfolio returns
across public and private markets for apartments.
6 Though unreported we obtain similar results when using equally weighted portfolios.
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We also notice that there are significant differences in specific gateway market performance
across property types. For example, the performance in Boston apartments and retail is significantly
lower than that of Boston industrial and office properties. Since equity REITs have chosen to
concentrate a larger proportion of their apartment and retail portfolio in Boston than NCREIF
investors, we again would expect these differences in concentration to significantly affect aggregate
comparisons of public and private market performance if not properly controlled for. However, in
property types and MSAs where geographic allocations do not vary much across investor groups (e.g.,
Chicago industrial) the impact on portfolio returns would be less important.
3.3. Adjusting Private Market Returns for Differences in MSA Concentrations
The observed differences in the MSA concentrations of core property investments and
performance across MSAs highlights the importance of controlling for MSA exposure when comparing
private market returns to the corresponding REIT returns, particularly if both public and private
investment managers have at least some discretion over the MSAs in which they are able to invest. We
therefore reweight NPI MSA-level returns using the time-varying MSA weights of the corresponding
REIT portfolio, as detailed in equation (1). In particular, for each core property type f, the total MSA-
weighted return in quarter t is defined as:
, , , , , , , . . . , , , 3 where , is the NPI total return for property type f in Metropolitan Statistical Area n in quarter t
and , is the (book value) weight of the REIT property portfolio concentrated in Metropolitan
Statistical Area n and property type f as of the beginning of year t. This weighting and aggregation
process is repeated each quarter to produce a time series of reweighted NPI returns for each of the four
core property types from 1996Q1 to 2013Q4. Note we hold our MSA weights, , , constant for each
quarter within a calendar year. However, the reweighted return ( , ) varies quarterly because
the MSA-level NPI return ( , ) varies quarterly.
We also construct an aggregate core property NPI total return series using SNL MSA weights.
We first calculate annual property type weights using the book value of all properties held by equity
REITs for each of the four core property type classifications. More specifically, the core portfolio weight
assigned to property type f in quarter t is:
, ,
∑ ,, 4
14
where f = 1…4 for multifamily (apartment), office, industrial and retail properties, respectively, and
BVf,T is the total book value of properties held by equity REITs classified as property type f as of the
beginning of year T.7 Thus, the total return in quarter t on our core-properties reweighted NPI index is
defined as:
, , , 5
where , is the total return on our reweighted NPI index for property type f in quarter t as
detailed in equation (3). This aggregation of property type NPI returns is repeated each quarter to
produce a time series of aggregate core reweighted NPI returns.
Table 4 provides summary statistics for the quarterly differences between our raw NPI and
reweighted NPI return series, by core property type and by reweighting methodology. The reweighted
mean NPI apartment return using book value weights (Panel A) varies little from the unadjusted NPI
apartment return over the 1996-2013 sample. The median return, standard deviation, and serial
correlation of the reweighted NPI apartment returns are also very similar in magnitude to the
corresponding summary statistics for the unadjusted NPI apartment returns.
The reweighted mean returns for industrial and office properties, using book value weights, are
2.5 and 3.8 basis points, respectively, greater than the corresponding unadjusted quarterly NPI return.
Thus, using reweighted returns slightly increases the average performance of industrial and office
NCREIF investors relative to the performance of REIT investors in these property types over the 1996-
2013 sample. In contrast, the reweighted mean return for retail NPI properties is 10.0 basis points
lower than the corresponding unadjusted NPI return; thus, its use in place of the unadjusted NPI
retail return decreases the measured relative performance of NCREIF investors.
The differences in geographically reweighted NPI returns and unadjusted NPI returns are very
similar when MSA weights are based on the adjusted cost of REIT properties (Table 4, Panel B). More
specifically, the mean reweighted NPI return for industrial and office properties are, respectively, 1.9
and 4.4 basis point higher than the unadjusted returns. For retail, the reweighted return is 10.6 basis
points lower than the unadjusted return.
The geographic reweighting of apartment, industrial, and office properties does not produce
notable differences in mean or median private market returns over the full sample when the weights 7 In alternate specifications, we also construct these property weights using our ADJCOST and PROPCOUNT variables as defined previously.
15
are based on book value or adjusted cost (Panels A and B). However, these sample means and medians
mask significant differences over time as shown by the large minimum and maximum differences in
Table 4. To better display this time-series variation in return differences, we plot quarterly differences
between reweighted and unadjusted NPI returns for apartment properties in Panel A of Figure 9. The
solid line captures quarterly differences in returns assuming MSA weights are based on the book value
of the underlying REIT properties. The dashed line plots differences using MSA weights based on the
adjusted cost of the underlying REIT properties. A point on any curve greater than zero percent
indicates the reweighted NPI return for apartments in that quarter is greater than the unadjusted NPI
return; that is, the unadjusted NPI return understates the performance of the NPI for the purpose of
comparing private market performance to returns on equity REITs.
Although the mean return difference for apartment properties is clearly centered around zero,
there are significant quarterly differences over the 1996 to 2013 sample period. For example, in the
second quarter of 2005, the reweighted NPI return (using book value) is less than the unadjusted
return by 0.97 percentage points (97 basis points), or 388 basis points annually. In contrast, the
reweighted NPI return is greater than the unadjusted NPI return in the first quarter of 2007 by 84
basis points, or 336 basis points annually. These are large and economically meaningful differences
that could significantly distort short-run comparisons between public and private real estate markets.
In Panels B-D of Figure 9, we plot quarterly differences in reweighted and unadjusted NPI total
returns for industrial, office and retail properties, respectively. Similar to apartment properties,
reweighting MSA-level NPI returns produces large changes in many quarters. For example, in the
fourth quarter of 2008, reweighted NPI returns are less than unadjusted office returns (using book
value geographic concentrations) by 165 basis points (660 basis points annually). In contrast,
reweighted NPI returns are greater than unadjusted NPI office returns by 137 basis points (548 basis
points annually) in the fourth quarter of 2006. Similarly large differences in quarterly returns are
observable in the industrial and retail property returns. In addition, the return differences can remain
positive, or negative, for sustained periods of time. The serial correlations of the return differences
(last column in Table 4), especially for industrial and office properties, also indicate statistically
significant persistence in return differences. Given that many investment management contracts have
durations of three-to-five years, these persistent differences could significantly affect the measured
performance of a manager.
16
4. Attribution Analysis
A primary objective is to better understand the extent to which the return differences in public
and private CRE markets reported in Table 1 are attributable to differences in MSA allocations versus
individual property selection and management within MSAs. It is generally impossible to define
unique, break-downs of total returns that correspond to clear investment management functions.
Nevertheless, useful insights can be obtained from performance attribution.
Assume that both REIT and NCREIF managers do not have discretion over the core property
type in which they invest. Assume also that the effects of leverage have been removed from the
underlying REIT returns in the REIT portfolio. Then, for property type f in year t, the difference in
REIT and NCREIF NPI total returns, , - , , is equal to:
, , = allocation + selection + interaction , (6)
where allocation is the portion of the return differential due to MSA allocations, selection is the portion
of the return differential due to property/asset picking and operational management, and interaction is
the portion of the return differential that resulted from the synergy between allocation and selection
decisions.
Using the total unlevered return earned by NCREIF managers on property type f in year t as
the benchmark, we can attribute the differential performance of REIT managers to allocation, ,
, , and selection, , , . The pure effect of REIT managers’ asset allocation, relative to the
benchmark return of NCREIF NPI mangers, is quantified as the sum across all MSAs of the difference
between REIT allocation and NCREIF allocation to an MSA, multiplied by the NCREIF NPI return in
that MSA. More formally, the return differential for property type f in year t attributable purely to
differences in MSA allocations is
, , = ⋯ , (7)
where is the NPI return in MSA n in year t, is the percentage of the REIT portfolio invested
in MSA n in year t, and is the percentage of the NCREIF portfolio invested in MSA n in year t.
The pure effect of REIT managers’ asset selection in year t, relative to the benchmark NCREIF
NPI return, is quantified as the sum across all MSAs of the difference between the REIT portfolio’s
return and the NPI return in an MSA, weighted by the allocation of the NCREIF NPI portfolio in that
MSA. More formally, the return differential attributable to property/asset selection MSA allocations is
17
, , = ⋯ , (8)
where is the return on the REIT portfolio in MSA n.
As detailed in equation (6), the sum of the pure allocation and selection effects do not equal the
total differential between REIT and NCREIF NPI returns. The remaining differential is due to the
combined effect of REIT managers’ allocation and selection performances interacting together.
Unfortunately, there is no meaningful way to disentangle this interaction effect and allocate it to
either one of the two pure effects. Typically, if the allocation of capital across MSAs is the primary
decision facing REIT and NCREIF managers, the interaction effect is added to the selection effect to
keep the allocation effect pure. This would be appropriate, in this application, if REIT mangers
generally pursued a top-down investment strategy (MSA selection then property selection). In contrast,
if REIT managers generally follow a bottom-up investment strategy—finding the best properties
without a primary concern for MSA allocations—it would be appropriate to add the interaction effect to
the allocation effect to keep the selection effect pure. However, data on REIT returns by property type
at the MSA level ( in equation (6) above) are not available. We are therefore unable to calculate a
pure selection effect (using the private market return series as our benchmark) and thus must lump
together the pure selection and interaction effects.
Performing attribution analysis for one quarter, as depicted in equation (7), is relatively
straight-forward if the MSA-level NPI returns ( ), as well as NPI and REIT MSA weights (
and ),are known. However, NPI and REIT portfolio allocations change over time and these
changes must be accounted for when explaining relative performance over the duration of a typical
asset management contract.
To facilitate a multi-year attribution analysis, we start with equation (7). Using the distributive
property and regrouping terms, equation (7) can be rewritten as
, , … ) -
… . 9
Note that the top term in parentheses is the return on the reweighted NPI for property type f in
quarter t (i. e. , , fromequation 3 , using REIT allocations for the reweighting. The bottom
term in parentheses is simply the “raw” NPI return for property type f in quarter t. Thus, by
subtracting the raw NPI return for a particular property type from the re-weighted NPI, we are left
with the pure allocation effect in quarter t using NPI as the benchmark.
18
For a T quarter analysis period, equation (9) can be rewritten as follows to produce the
geometric average return over T quarters:
, , ∏ 1 , -1) – ( ∏ 1 , - 1) . (10)
Table 5 displays results from our attribution analysis using NPI returns as the benchmark for each of
the four core property types, as well as the aggregate core property type series. We report the quarterly
difference in geometric means between our unlevered REIT returns and the raw NPI returns, the
geometric mean of the pure allocation effect, and the geometric mean of the selection plus interaction
effects for the following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013. In each of the core
property types and for all reported return horizons, the allocation effect constitutes a small portion of
the total return difference, relative to the selection plus interaction effects. This indicates that the
decision to allocate to a particular MSA is relatively less important than the manager’s ability to select
properties within that MSA. However, the sign and magnitude of the allocation effect varies
significantly over the period and property type being examined. For example, in the retail property
type, the allocation decisions of REIT managers resulted in a 10 (40) basis point quarterly (annual)
underperformance relative to the private market benchmark over the full sample period. However, the
asset selection (plus interaction) of REIT managers resulted in a 27 (107) basis point outperformance of
the benchmark portfolio. In this case the allocation effect reduced the value added of the manager’s
selection ability. In contrast, if we focus on the pure allocation effect in the industrial property type,
the difference in allocations across markets resulted in value added over three of the four sample
periods examined.
4.1. Robustness Check Using REIT Returns as the Benchmark
As discussed above, data on REIT returns by property type at the MSA level are not available.
We therefore were unable to calculate a pure selection effect using NPI returns as the benchmark;
thus, we included the selection effect with the interaction effect. However, if we instead use REIT
returns as the benchmark, we are able to compute a pure selection effect that can be compared to our
results using NPI returns as the benchmark.
The pure effect of NCREIF managers’ selection, relative to the benchmark REIT return, is
quantified as the sum across all MSAs of the difference between the NPI returns and returns on the
REIT portfolio, weighted by the allocation of the REIT portfolio in each MSA. More formally, the
19
return differential between NPI returns and REIT returns in quarter t attributable purely to
property/asset selection and management is
, , = ⋯ . (11)
Using the distributive property and regrouping terms, equation (11) can be rewritten as:
, , … ) -
… . 12
The top term in parentheses is the return on the reweighted NPI for property type f in quarter t
(i. e. , , fromequation 3 , using REIT allocations for the reweighting. The bottom term in
parentheses is the REIT return in quarter t where each MSA-level REIT return is weighted by the
REIT allocation to the MSA in quarter t. Upon inspection of equation (11) it appears the pure selection
effect using REIT returns as a benchmark cannot be computed because we do not know MSA-level
REIT returns ( , ). However, we are able to compute the second summation in equation (12); that
is, we can compute the mean annualized return for unlevered REITs of property type f over any
holding period within our 1996-2013 quarterly sample period. Thus, by subtracting the unlevered
REIT series for a particular property type from the reweighted NPI return, we are left with the pure
selection effect using REIT returns as the benchmark.
For a T quarter analysis period, equation (12) can be rewritten as follows to produce the
average annualized return over T quarters:
, , ∏ 1 , -1) – ( ∏ 1 , - 1) . (13)
As before, the sum of the pure selection effect and allocation effect do not equal the total differential
between NPI and REIT returns. The remaining differential is due to the combined effect of REIT
managers’ selection and allocation performances interacting together. As discussed above, if NCREIF
managers generally follow a bottom-up investment strategy—finding the best properties without a
primary concern for MSA allocations—it is appropriate to add the interaction effect to the allocation
effect to keep the selection effect pure. However, because REIT returns by property type at the MSA
level are not available, we are unable to calculate a pure allocation effect using REIT returns as the
benchmark. Therefore, we must lump together the pure allocation effects and interaction effects.
20
Table 6 displays results from our attribution analysis using REIT returns as the benchmark for each of
the four core property types, as well as the aggregate core property type series. We report the quarterly
difference in geometric means between our raw NPI returns and our unlevered REIT returns, the
geometric mean of the pure selection effect, and the geometric mean of the allocation plus interaction
effects for the following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013. Examination of
Table 6 confirms our previous results reported in Table 5 when using the NPI as our benchmark return
series. In particular, the selection effect is the most significant portion of the return difference between
private and public market portfolios.
5. A Simplified Example: Equity Residential
The discussion to this point has centered on controlling for differences in geographic
concentrations between public and private market investors in an attempt to provide a better
benchmark for return comparisons as well as insights on the importance of allocation and selection in
return performance at the portfolio level. However, our methodology can easily be applied on a firm
level basis. For example, REIT managers can utilize our reweighting procedure to generate a private
benchmark return series that is “geographically identical” to their particular portfolio. They also can
utilize the attribution framework to better understand how allocation and selection decisions impact
firm return performance.
We consider the case of Equity Residential (EQR), a large multifamily (apartment) REIT, to
implement our framework on a firm level basis. In particular, we construct unlevered REIT returns for
EQR on a quarterly basis following the methodology of Ling and Naranjo (2015). For our initial
comparison to a private market benchmark, we utilize quarterly raw NPI returns for the apartment
property type. We then create a reweighted NPI return series using MSA-level returns and the time-
varying MSA weights of EQR’s property portfolio, as detailed in equation (1). In particular, for EQR,
the total MSA-weighted return in quarter t is defined as:
, , , , , , , . . . , , , 14 where , is the NPI total return in Metropolitan Statistical Area n in quarter t and , is the
(book value) weight of EQR’s property portfolio concentrated in Metropolitan Statistical Area n as of
the beginning of year t.
Panel A of Table 7 reports the geometric means for EQR’s unlevered REIT returns, the raw NPI
apartment returns, and the reweighted NPI return series using EQR’s geographic concentrations as
21
weights for the following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013. Over each return
horizon, the raw NPI series overstates benchmark returns, though the differences are relatively small
in magnitude. For example, over the full sample period there is a 2.5 (10) basis point quarterly
(annually) difference between the raw NPI and the reweighted NPI that makes use of EQR’s
geography composition. Therefore, the use of the raw NPI series leads to an overstatement in the
relative underperformance of EQR to its private market benchmark. During the period of real estate
expansion (2002-2007), the magnitude of this effect is a bit larger. The raw NPI overstates the
benchmark performance by 5.5 (22) basis points quarterly (annually) over this horizon. While these
differences are relatively small, we expect there to be significant cross-sectional variation across equity
REITs. In particular, we expect this reweighting procedure to matter most for firms whose geographic
concentration differs significantly from that of the benchmark property type NPI series.
Panel B of Table 7 reports results from our firm level attribution analysis. In particular we
decompose the return difference between EQR’s unlevered returns and the raw NPI apartment returns
into a pure allocation effect and selection plus interaction effects. We report geometric means of our
return components over the following periods: 1996-2001, 2002-2007, 2008-2013, and 1996-2013.
Consistent with our earlier results at the portfolio level, we find that the pure allocation effect
constitutes a small portion of the total return difference, relative to the selection plus interaction
effects. For example, over our full sample period the allocation effect constituted 2.5 (10) basis points of
the 21 (84) basis point quarterly (annual) difference between EQR’s unlevered returns and the NPI
benchmark series.
6. Conclusion
While private and public REIT markets can provide investors with exposure to the same
underlying local property markets, they often exhibit significantly different risk-return characteristics.
This paper examines the impact of differences in geographic portfolio concentrations on return
performance comparisons of U.S. public and private commercial real estate investors over the 1996-
2013 time period. By adjusting returns for differences between public and private markets in financial
leverage, property type focus, management fees, and geographic concentrations we are able to more
accurately assess the relative performance of “geographically identical” public and private market
portfolios. Furthermore, through formal attribution analysis, we are able to disentangle whether the
relative return performance is attributable to differences in MSA allocations or individual property
selection and management within MSAs.
22
In comparing the MSA concentrations of publicly-traded REITs, by core property type, to the
MSA concentrations of the properties in the NCREIF database, we document significant differences in
geographic allocations of property portfolios between public and private market investors. Since these
differences vary significantly over time and across property type classifications, we find that
accounting for time-series and cross-sectional differences in the geographic concentrations of the
properties held by core equity REITs and NCREIF investors significantly impacts the performance
comparison across markets.
Controlling for the geographic composition of property portfolios in these two markets, we
continue to find that public market real estate returns outperform comparable private market returns.
Through our attribution analysis, we find that the MSA allocation effect constitutes a small portion of
the total return difference relative to selection effects. This result indicates that the decision to allocate
to a particular MSA is relatively less important than the manager’s ability to select properties within
that MSA. Taken together, our results suggest that additional follow-on research examining real estate
geographic allocation and selection effects is important to understanding return performance and
effective investment strategies.
References
Ambrose, B., S. Ehrlich, W. Hughes and S. Wachter. 2000. REIT Economies of Scale: Fact or Fiction? The Journal of Real Estate Finance and Economics 20: 211–224. Campbell, R., Petrova, M., Sirmans, C.F.. 2003. Wealth effects of diversification and financial deal structuring: evidence from REIT property portfolio acquisitions. Real Estate Economic 31, 347–366. Capozza, D.R. and P.J. Seguin. 1998. Managerial Style and Firm Value. Real Estate Economics 26: 131–150. Capozza, D.R. and P.J. Seguin. 1999. Focus, Transparency, and Value: The REIT Evidence. Real Estate Economics 27: 587–619. Cici, Gjergji, Jack Corgel, and Scott Gibson. 2011. Can Fund Managers Select Outperforming REITs? Examining Fund Holdings and Trades. Real Estate Economics 39: pgs. 455-486. Gyourko, J. and E. Nelling. 1996. Systematic Risk and Diversification in the Equity Market. Real Estate Economics 24: 493–515. Hartzell, Jay C., Libo Sun, and Sheridan Titman. 2014. Institutional investors as monitors of corporate diversification decisions: Evidence from real estate investment trusts. Journal of Corporate Finance 25: pgs. 61-72.
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Hochberg, Yael V. and Tobias Muhlhofer. 2014. Market Timing and Investment Selection: Evidence from Real Estate Investors. Working Paper. Ling, David C. and Andy Naranjo. 2015. Returns and Information Transmission Dynamics in Public and Private Real Estate Markets. Real Estate Economics, Forthcoming. Riddiough, Timothy J., Mark Moriarty, and P.J. Yeatman. 2005. Privately versus Publicly Held Asset Investment Performance. Real Estate Economics 33: pgs. 121-146. Tsai, Jengbin Patrick. 2007. A Successive Effort on Performance Comparison between Public and Private Real Estate Equity Investment. Working Paper.
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Figure 1: Gateway City Concentrations of Core Properties – NCREIF vs. REITs This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in Gateway cities for all core property types over the 1996-2013 sample period. Gateway cities are defined as Boston, Chicago, Los Angeles, New York, San Francisco, and Washington, D.C. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities.
25
Figure 2: Gateway City Concentrations by Core Property Type – NCREIF vs. REITs
This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in Gateway cities for each of the four core property types over the 1996-2013 sample period. Gateway cities are defined as Boston, Chicago, Los Angeles, New York, San Francisco, and Washington, D.C. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities.
Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
26
Figure 3: Geographic Concentrations – NCREIF vs. REITs (Chicago)
This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in Chicago for each of the four core property types over the 1996-2013 sample period. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities.
Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
27
Figure 4: Geographic Concentrations – NCREIF vs. REITs (Los Angeles)
This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in Los Angeles for each of the four core property types over the 1996-2013 sample period. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities. Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
28
Figure 5: Geographic Concentrations – NCREIF vs. REITs (New York)
This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in New York for each of the four core property types over the 1996-2013 sample period. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities. Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
29
Figure 6: Geographic Concentrations – NCREIF vs. REITs (Washington, D.C.)
This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in Washington, D.C. for each of the four core property types over the 1996-2013 sample period. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities.
Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
30
Figure 7: Geographic Concentrations by Core Property Type – NCREIF vs. REITs (Boston) This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in Boston for each of the four core property types over the 1996-2013 sample period. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities. Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
31
Figure 8: Geographic Concentrations by Core Property Type – NCREIF vs. REITs (San Francisco) This figure plots the geographic concentrations of private (NCREIF) and public (equity REIT) commercial real estate portfolios in San Francisco for each of the four core property types over the 1996-2013 sample period. Private market concentrations are calculating using market (appraised) value of each core property held by the NCREIF NPI in gateway cities. Public market concentrations are calculated using reported book value of each core property held by equity REITs in gateway cities. Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
32
Figure 9: Differences in Reweighted NPI Returns and Raw NPI Returns
This figure plots quarterly differences between the reweighted and unadjusted NPI return series for each of the four core property types. The solid line captures quarterly differences in returns assuming MSA weights are based on the book value of the underlying REIT properties. The dashed line plots differences using MSA weights based on the adjusted cost of the underlying REIT properties.
Panel A: Multifamily (Apartments) Panel B: Industrial
Panel C: Office Panel D: Retail
33
Table 1: Average Return Comparison: Public and Private Real Estate Markets
This table reports quarterly geometric means of our unlevered equity REIT returns, unlevered raw NPI returns, and the difference between the two series over the following periods: 1996-2001, 2002-2007, 2008-2013, 1996-2013. Returns are reported in percentage form.
Panel A: Unlevered Equity REIT Returns
1996-
2001 2002- 2007
2008- 2013
1996- 2013
Apartment 2.584 2.022 1.728 2.111 Industrial 2.560 3.439 0.133 2.034 Office 2.734 2.346 1.205 2.093 Retail 2.333 3.184 1.692 2.401 Aggregate: Core Properties 2.393 2.650 1.511 2.183
Panel B: Unlevered Raw NPI Returns
1996- 2001
2002- 2007
2008- 2013
1996- 2013
Apartment 2.696 2.879 0.840 2.134 Industrial 2.986 2.926 0.585 2.159 Office 3.095 2.913 0.372 2.119 Retail 1.828 3.742 1.146 2.233 Aggregate: Core Properties 2.637 3.066 0.700 2.129
Panel C: Unlevered REIT Returns minus Unlevered Raw NPI Returns
1996- 2001
2002- 2007
2008- 2013
1996- 2013
Apartment -0.113 -0.857 0.888 -0.024 Industrial -0.426 0.513 -0.452 -0.125 Office -0.361 -0.567 0.833 -0.026 Retail 0.505 -0.558 0.546 0.169 Aggregate: Core Properties -0.245 -0.416 0.811 0.054
34
Table 2: Average NPI Return Comparison: Gateway and Non-Gateway Markets
This table reports quarterly geometric means of unlevered raw NPI returns for gateway and non-gateway markets, and the difference between the two series for each of the four core property types, and all core properties, over the following periods: 1996-2001, 2002-2007, 2008-2013, 1996-2013. Return series are value-weighted based on the market (appraised) value of the properties held by the NCREIF NPI. Gateway cities are defined as Boston, Chicago, Los Angeles, New York, San Francisco, and Washington, D.C. Returns are reported in percentage form.
Panel A: Gateway NPI Returns
1996- 2001
2002- 2007
2008- 2013
1996- 2013
Apartment 3.507 3.376 0.612 2.490 Industrial 3.345 3.437 0.761 2.507 Office 3.388 3.618 0.673 2.551 Retail 2.239 4.308 1.457 2.661 Aggregate: Core Properties 3.114 3.627 0.781 2.500
Panel B: Non-Gateway NPI Returns
1996- 2001
2002- 2007
2008- 2013
1996- 2013
Apartment 2.832 2.979 1.278 2.360 Industrial 3.139 3.045 0.789 2.319 Office 3.237 2.664 0.457 2.112 Retail 1.962 3.813 1.321 2.360 Aggregate: Core Properties 2.690 3.063 0.970 2.237
Panel C: Gateway NPI Returns minus Non-Gateway NPI Returns
1996- 2001
2002- 2007
2008- 2013
1996- 2013
Apartment 0.675 0.397 -0.666 0.129 Industrial 0.206 0.392 -0.028 0.188 Office 0.151 0.955 0.217 0.439 Retail 0.277 0.496 0.136 0.302 Aggregate: Core Properties 0.424 0.564 -0.189 0.263
35
Table 3: Average Return Comparison: Individual Gateway Markets
This table reports quarterly geometric means of unlevered raw NPI returns for individual gateway markets for each of the four core property types over the following periods: 1996-2001, 2002-2007, 2008-2013, 1996-2013. Return series are value-weighted based on the market (appraised) value of the properties held by the NCREIF NPI. Gateway cities are defined as Boston, Chicago, Los Angeles, New York, San Francisco, and Washington, D.C. Returns are reported in percentage form.
Panel A: Apartment 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Chicago 3.218 2.527 1.573 2.437 Los Angeles 2.041 3.631 0.798 2.150 New York 0.732 3.189 -0.289 1.200 Washington, D.C. 3.824 4.071 1.376 3.083 Boston - 1.157 1.593 0.914 San Francisco - 3.264 1.985 1.741
Panel B: Industrial 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Chicago 2.585 2.669 0.454 1.898 Los Angeles 3.537 4.015 0.852 2.792 New York 3.204 3.292 1.396 2.627 Washington, D.C. 3.785 3.593 1.129 2.829 Boston 4.073 1.797 -0.539 1.759 San Francisco 4.170 3.025 0.768 2.644
Panel C: Office 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Chicago 3.171 2.201 0.227 1.859 Los Angeles 3.285 3.916 0.532 2.567 New York 3.415 4.649 0.785 2.937 Washington, D.C. 2.884 3.794 0.949 2.535 Boston 4.017 3.767 -0.081 2.550 San Francisco 4.607 2.605 1.090 2.757
Panel D: Retail 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Chicago 1.749 4.045 1.491 2.422 Los Angeles 2.683 4.325 1.078 2.687 New York 2.793 4.600 1.812 3.062 Washington, D.C. 1.875 4.733 1.554 2.711 Boston - 2.682 0.209 0.956 San Francisco 3.179 4.252 1.867 3.095
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Table 4: Reweighted NPI Returns minus Unadjusted NPI Returns
This table reports summary statistics of the quarterly differences between our reweighted NPI returns and the raw NPI returns for each of the core property types, and all core properties, over the 1996-2013 sample period. Returns are reported in percentage form. ***, **, and * represent 1%, 5%, and 10% significance levels respectively.
Panel A: Using Book Value (BV) Reweighting of NCREIF MSA Returns
Mean
Median
Std Dev
Min
Max Serial
Correlation Apartment -0.002 0.021 0.290 -0.973 0.842 -0.08 Industrial 0.025 0.021 0.303 -0.593 1.050 0.40*** Office 0.038 0.006 0.393 -1.649 1.371 0.18* Retail -0.100 -0.065 0.374 -1.662 0.818 0.02 Aggregate: Core Properties -0.024 -0.024 0.406 -0.947 1.279 0.63***
Panel B: Using Adjusted Cost (ADJCOST) Reweighting of NCREIF MSA Returns
Mean
Median
Std Dev
Min
Max Serial
Correlation Apartment 0.000 0.012 0.284 -0.941 0.765 -0.07 Industrial 0.019 0.017 0.318 -0.787 1.042 0.45*** Office 0.044 0.008 0.348 -1.369 1.175 0.19* Retail -0.106 -0.071 0.378 -1.696 0.763 0.02 Aggregate: Core Properties -0.017 -0.029 0.391 -0.829 1.292 0.61***
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Table 5: Attribution Analysis Using NPI as Benchmark and Book Value Weights This table reports quarterly geometric means of our attribution analysis using NPI as the benchmark for each of the four core property types over the following periods: 1996-2001, 2002-2007, 2008-2013, 1996-2013. Returns are reported in percentage form. Panel A: Apartment 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Unlevered REIT return minus raw NPI -0.113 -0.857 0.888 -0.024 Pure allocation effect -0.004 -0.065 0.062 -0.002 Selection effect plus interaction -0.109 -0.792 0.826 -0.022 Panel B: Industrial 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Unlevered REIT return minus raw NPI -0.426 0.513 -0.452 -0.125 Pure allocation effect -0.073 0.096 0.060 0.028 Selection effect plus interaction -0.353 0.417 -0.512 -0.153 Panel C: Office 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Unlevered REIT return minus raw NPI -0.361 -0.567 0.833 -0.026 Pure allocation effect 0.009 -0.020 0.113 0.035 Selection effect plus interaction -0.370 -0.547 0.720 -0.061 Panel D: Retail 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Unlevered REIT return minus raw NPI 0.505 -0.558 0.546 0.169 Pure allocation effect -0.020 -0.172 -0.105 -0.099 Selection effect plus interaction 0.525 -0.386 0.651 0.267 Panel E: Core Properties (Aggregate) 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Unlevered REIT return minus raw NPI -0.245 -0.416 0.811 0.054 Pure allocation effect -0.217 -0.019 0.174 -0.019 Selection effect plus interaction -0.027 -0.397 0.637 0.074
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Table 6: Attribution Analysis Using REITs as Benchmark This table reports quarterly geometric means of our attribution analysis using equity REITs as the benchmark for each of the four core property types over the following periods: 1996-2001, 2002-2007, 2008-2013, 1996-2013. Returns are reported in percentage form. Panel A: Apartment 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Raw NPI return minus Unlevered REIT return 0.113 0.857 -0.888 0.024 Pure selection effect 0.109 0.792 -0.826 0.022 Allocation effect plus interaction 0.004 0.065 -0.062 0.002 Panel B: Industrial 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Raw NPI return minus Unlevered REIT return 0.426 -0.513 0.452 0.125 Pure selection effect 0.353 -0.417 0.512 0.153 Allocation effect plus interaction 0.073 -0.096 -0.060 -0.028 Panel C: Office 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Raw NPI return minus Unlevered REIT return 0.361 0.567 -0.833 0.026 Pure selection effect 0.370 0.547 -0.720 0.061 Allocation effect plus interaction -0.009 0.020 -0.113 -0.035 Panel D: Retail 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Raw NPI return minus Unlevered REIT return -0.505 0.558 -0.546 -0.169 Pure selection effect -0.525 0.386 -0.651 -0.267 Allocation effect plus interaction 0.020 0.172 0.105 0.099 Panel E: Core Properties (Aggregate) 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Raw NPI return minus Unlevered REIT return 0.245 0.416 -0.811 -0.054 Pure selection effect 0.027 0.397 -0.637 -0.074 Allocation effect plus interaction 0.217 0.019 -0.174 0.019
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Table 7: Sample Firm Analysis – Equity Residential (EQR) This table reports quarterly geometric means of the unlevered REIT return for Equity Residential, the raw NPI apartment return series, the reweighted NPI index using Equity Residential’s geographic allocations, and firm level attribution analysis using the NCREIF NPI as the benchmark over the following periods: 1996-2001, 2002-2007, 2008-2013, 1996-2013. Returns are reported in percentage form. Panel A: Return Series 1996-
2001 2002- 2007
2008- 2013
1996- 2013
Unlevered REIT Return (EQR) 2.177 2.619 1.581 2.125 Raw NPI Returns - Apartment 2.896 3.079 1.040 2.334 Reweighted NPI Returns (using EQR Weights) 2.887 3.024 1.029 2.309 Panel B: Attribution Analysis
1996- 2001
2002- 2007
2008- 2013
1996- 2013
Unlevered REIT return (EQR) minus raw NPI - Apartment -0.719 -0.461 0.541 -0.210 Pure allocation effect -0.009 -0.056 -0.011 -0.025 Selection effect plus interaction -0.710 -0.405 0.552 -0.185